MECHANISMS OF THE COMPLEX FORMATION BY d-METALS ON POROUS SUPPORTS AND THE CATALYTIC ACTIVITY OF THE FORMED COMPLEXES IN REDOX REACTIONS
Journal Title: Вісник Одеського національного університету. Хімія - Year 2015, Vol 20, Issue 2
Abstract
The catalytic activity of supported complexes of d metals in redox reactions with participation of gaseous toxicants, PH3, CO, O3, and SO2, depends on their composition. Owing to the variety of physicochemical and structural-adsorption properties of available supports, their influence on complex formation processes, the composition and catalytic activity of metal complexes anchored on them varies over a wide range. The metal complex formation on sup-ports with weak ion-exchanging properties is similar to that in aqueous solutions. In this case, the support role mainly adds up to the ability to reduce the activity of water adsorbed on them. The interaction between a metal complex and a support surface occurs through adsorbed water molecules. Such supports can also affect complex formation processes owing to protolytic reactions on account of acidic properties of sorbents used as supports. The catalytic activity of metal complexes supported on polyphase natural sorbents considerably depends on their phase relationship. In the case of supports with the nonsimple structure and pronounced ion-exchanging properties, for instance, zeolites and laminar silicates, it is necessary to take into account the variety of places where metal ions can be located. Such location places determine distinctions in the coordination environment of the metal ions and the strength of their bonding with surface adsorption sites and, therefore, the catalytic activity of surface complexes formed by theses metal ions. Because of the energy surface inhomogeneity, it is important to determine a relationship between the strength of a metal complex bonding with a support surface and its catalytic activity. For example, bimetallic complexes are catalytically active in the reactions of oxidation of the above gaseous toxicants. In particular, in the case of carbon monoxide oxidation, the most catalytic activity is shown by palladium-copper complexes in which copper(II) is strongly fixed on a support surface as a result of the ion exchanging and palladium(II) is bound with copper(II) through a water molecule or some other ligands. The formation of surface complexes can occur as a result of the covalent binding of 3d metals with ligands preliminarily immobilized on supports. However, the examined complexes with aerosol immobilized Schiff bases are catalytically active only in the reaction of ozone decomposition.
Authors and Affiliations
T. L. Rakitskaya, A. S. Truba, T. O. Kiose, L. A. Raskola
Keywords
Related Articles
- EP ID EP408767
- DOI 10.18524/2304-0947.2015.2(54).50626
- Views 90
- Downloads 0
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